MIM capacitor with plate having high melting point

ABSTRACT

A method for producing an integrated device including an MIM capacitor. The method includes the steps of providing a functional substrate including functional circuits of the integrated device, forming a first conductive layer including a first plate of the capacitor on the functional substrate; the first plate has a first melting temperature. The method further includes depositing a layer of insulating material including a dielectric layer of the capacitor on a portion of the first conductive layer corresponding to the first plate; the layer of insulating material is deposited at a process temperature being lower than the first melting temperature. The method further includes forming a second conductive layer including a second plate of the capacitor on a portion of the layer of insulating material corresponding to the dielectric layer. In the solution according to an embodiment of the invention, the first melting temperature is higher than 500° C.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the priority benefit of Italian patent application number MI2009A002353, filed on Dec. 30, 2009, entitled “MIM Capacitor with Plate Having High Melting Point,” which is hereby incorporated by reference to the maximum extent allowable by law.

BACKGROUND OF THE INVENTION

1. Field of the Invention

An embodiment of the present invention relates to the microelectronics field. More specifically, the present invention relates to integrated capacitors.

2. Discussion of the Related Art

Capacitors are components commonly used in most electronic circuits. Referring in particular to an electronic device being integrated in a chip of semiconductor material, many techniques are known for making the capacitors in the same chip wherein there are made other functional components of the integrated device, being both passive (such as resistors) and active (such as transistors).

For example, (integrated) Metal-Oxide-Metal (MOM) capacitors include two plates of conductive material (typically metal) between which there is grown a thin oxide layer of the metal (having insulating properties) to form a dielectric layer of the capacitor. The MOM capacitors are nowadays the preferred choice in many types of integrated devices for their manufacturing simplicity, even if they need particular manufacturing precautions in order not to damage the thin oxide layer.

On the contrary, (integrated) Metal-Insulator-Metal (MIM) capacitors are formed by two plates of conductive material (typically metal) between which there is deposited a layer of insulating material (for example, Silicon Nitride) to form the dielectric layer of the capacitor. The Silicon Nitride has a high dielectric constant, so that the MIM capacitors have a specific capacitance (per unit area of their plates) being greater than that of the MOM capacitors; this allows making more compact capacitors that, for the same overall capacity, occupy a lower area of the chip than the MOM capacitors do. Furthermore, the MIM capacitors allow integrating other components below them, with a further saving of area of the chip.

Typically, each MIM capacitor is made by forming a bottom plate thereof from a portion of a metal layer of the chip, being commonly used for distributing signals and/or power supply among functional components of the integrated device, while an upper plate thereof is formed within a protective layer (of insulating material) protecting the metal layer wherein there are made the bottom plate and the dielectric layer being formed thereon.

However, in the present state of the art, the quality of the dielectric layer of the MIM capacitors is not optimal. In fact, the layer of insulating material from which there is formed the dielectric layer is typically obtained through a deposition process on the bottom plate of the MIM capacitor; such deposition should be performed at temperatures such that the bottom plate is not damaged. Since the metal layer (from which the bottom plate is obtained) that are typically used in the integrated devices has a relatively low melting temperature (usually, not grater than 400° C.), the dielectric layer has to be deposited necessarily at process temperatures that are not optimal (for example, 200° C.). This has a negative effect on the chemical and mechanical properties of the dielectric layer, such as the planarity, with a consequent worsening of its insulating properties.

Furthermore, the low melting temperature of the bottom plate turns out to be particularly critical in power applications; particularly, when the MIM capacitors are integrated together with power components, the bottom plate should have a well-defined thickness depending on the requirements of the power components. For example, in the case of bipolar-CMOS-DMOS (BCD) technology—where BJTs for precision analog applications, CMOS for digital applications, and DMOS for power applications are integrated in the same chip—the metal layer (and thus the bottom plate of the capacitor) has a typical thickness of 0.7-1.0 μm (for limiting an ON-resistance of the power components and for reducing electro-migration phenomena). If the bottom plate has a low melting temperature, it is more subject to thermo-plastic deformations being due to thermal stresses during the operations following its manufacturing; this involves a thick-grained structure of the bottom plate, which causes kinks and surface irregularities that affect not only the performance of the capacitor (such as a voltage breakdown thereof) but also the performance of the power components.

SUMMARY OF THE INVENTION

In its general terms, an embodiment of the present invention is based on the idea of using a bottom plate having a high melting temperature.

Particularly, several aspects of an embodiment of the invention are set out in the independent claims. Advantageous features of the same solution are set forth in the dependent claims.

More specifically, an aspect of an embodiment of the invention provides a method for producing an integrated device including an MIM capacitor. The method includes the steps of providing a functional substrate including functional circuits of the integrated device, forming a first conductive layer including a first plate of the capacitor on the functional substrate; the first plate has a first melting temperature. The method further includes depositing a layer of insulating material including a dielectric layer of the capacitor on a portion of the first conductive layer corresponding to the first plate; the layer of insulating material is deposited at a process temperature being lower than the first melting temperature. The method further includes forming a second conductive layer including a second plate of the capacitor on a portion of the layer of insulating material corresponding to the dielectric layer. According to an embodiment of the invention, the first melting temperature is higher than 500° C.

Another embodiment of the invention provides a corresponding integrated device.

An embodiment of the invention provides a complex system including one or more of such integrated devices.

BRIEF DESCRIPTION OF THE DRAWINGS

Embodiments of the invention, as well as further features and the advantages thereof, will be best understood with reference to the following detailed description, given purely by way of a non-restrictive indication, to be read in conjunction with the accompanying drawings (wherein corresponding elements are denoted with equal or similar references, and their explanation is not repeated for the sake of exposition brevity). In this respect, it is expressly intended that the figures are not necessarily drawn to scale and that, unless otherwise indicated, they are simply used to conceptually illustrate the described structures and procedures. In particular:

FIG. 1A-1G schematically show various steps of a production process of an integrated device including an MIM capacitor according to an embodiment of the invention, and

FIG. 2A-2G schematically show various steps of a production process of an integrated device including an MIM capacitor according to another embodiment of the invention.

DETAILED DESCRIPTION

The various steps of a production process of an integrated device including an MIM capacitor according to an embodiment of the invention are illustrated in FIG. 1A-1G. In general, the production process is performed at the level of a wafer of semiconductor material, in which identical integrated devices (each one including one or more of such capacitors) are made simultaneously in large numbers in order to be separated at the end through a cutting operation (for simplicity of description, however, in the following reference will be made to only one of such integrated devices).

Considering in particular FIG. 1A, the description of the production process begins once a functional substrate 105 has been obtained. Such functional substrate 105 includes an operative layer 110 in a lower portion thereof—for example, a silicon substrate on which an epitaxial layer is grown; the operative layer 110 includes functional components of the integrated device (for example, resistors and transistors), being not shown in the figure. Furthermore, the functional substrate 105 includes one or more conductive areas 115 and a conductive area 118 (or more) on the operative layer 110, which are derived from a common conductive layer (for example, of polysilicon). Each conductive area 115 is used for electrically connecting the functional components included in a corresponding portion of the operative layer 110, while the conductive area 118 is used for electrically contacting a bottom plate of the capacitor (as described in detail in the following). The functional substrate 105 also includes an insulating layer 120, commonly called Pre-Metal Dielectric or PMD, which is deposited on the conductive areas 115, 118 and on portions of the operative layer 110 being not covered by the conductive areas 115, 118.

Turning now to FIG. 1B, within the pre-metal layer 120 there are made one or more via-holes 125 (only one shown in the figure) for contacting corresponding conductive areas 115 (and hence the functional components included in the corresponding portions of the operative layer 110 on which such conductive areas 115 are formed) to upper layers of the integrated device. Similarly, within the pre-metal layer 120 there are made one or more via-holes 126 (three in the example in the figure) and a via-hole 128 (or more) for contacting the bottom plate of the capacitor below it and outside it, respectively (as described in detail in the following).

With reference now to FIG. 1C, the production process continues with the deposition on the functional substrate 105 of a layer of metal material 130, on which there is then deposited a layer of insulating material 135 (from which there will be derived a bottom plate of the capacitor and a dielectric layer of the capacitor, respectively, as described in detail in the following).

The layer of metal material 130 should have a melting point, defined as the value of temperature and pressure at which solid and liquid phases coexist in thermodynamic equilibrium, being higher than the values of temperature and pressure at stake in the subsequent deposition process of the layer of insulating material 135, so that the layer of metal material 130 does not melt during the deposition of the layer of insulating material 135.

According to an embodiment of the invention, the layer of metal material 130 is made of a refractory material, which has a melting point being higher than the values of the melting points of the traditional materials.

For example, the layer of refractory material 130, at room pressure (i.e., 760 Torr) has a melting temperature being higher than 500° C., and preferably higher than 800° C. (for example, higher than 850° C.); in particular, such melting temperature is between 500° C. and 1500° C., preferably between 800° C. and 1300° C., and even more preferably between 850° C. and 1200° C. Conductive materials that exhibit such features are, for example, metals and alloys containing Nitride (for example, Ti_(x)N_(y), TaNTa, Ti_(x), TiN, W_(x)N_(y), Hf_(x)N_(y)).

In this way, it is possible to increase a deposition temperature of the layer of insulating material 135 accordingly (with such deposition that should however occur at a temperature being lower than the melting one of the layer of refractory material 130). As a consequence, the layer of insulating material 135 may be deposited at high temperatures (without the risk of melting the layer of refractory material 130 below it)—for example, higher than 400° C., and preferably higher than 600° C. (such as between 700° C. and 1000° C., and preferably between 800° C. and 900° C.). For example, the layer of insulating material 135 may be deposited by using a technique being known as LPCVD (Low Pressure Chemical Vapor Deposition), which identifies a procedure that provides for gas-phase components reacting at the surface of a substrate (in this case, the layer of refractory material 130) to form a solid deposit. The LPCVD process is performed at low pressure (for example, between 250 mTorr and 1500 mTorr, and preferably between 300 mTorr and 1200 mTorr, such as 400 mTorr) and at high temperature (for example, between 500° C. and 1000° C., and preferably between 800° C. and 900° C., such as 850° C.). Materials that in such process conditions are suitable for use as a layer of insulating material 135 are, for example, Silicon Nitride, or a combination Oxygen-Oxygen-Nitride (ONO).

The deposition at high temperatures has a positive effect on the chemical and mechanical properties of the layer of insulating material 135 (and hence of the dielectric layer of the capacitor), with a consequent improvement of its insulating properties.

Moreover, the layer of refractory material 130 (and thus the bottom plate of the capacitor) is substantially unaffected by thermo-plastic deformations being due to thermal stresses during the operations after its manufacturing; this involves better performance of the capacitor and of the whole integrated device in critical conditions that may occur in particular applications (such as, for example, in power applications).

After the deposition process, a photo-resist mask, not shown in the figure, is made on the layer of insulating material 135 through a photo-lithographic technique; portions of the layer of insulating material 135 and of the layer of refractory material 130 being not protected by the mask are etched—for example, through a dry etching operation. The result of such operation is shown in FIG. 1E, where a corresponding dielectric layer 140 and a corresponding layer of refractory material 145 of the capacitor are obtained after the stripping of the mask. As it can be seen in such figure, under the dielectric layer 140 there is thus formed a bottom plate 145 of the capacitor, which contacts the via-holes 126 below it.

The process continues in FIG. 1E with the deposition of a metal layer 160 on the dielectric layer 140, the via-holes 125, 128 and the exposed surface of the functional substrate 105; the metal layer 160 is then patterned by a masking and etching operation.

The result of such operation is shown in FIG. 1F, after the stripping of the respective mask. As it can be seen, a residual portion of the metal layer on the dielectric layer 140 defines a top plate 165 of the capacitor. In this way, there is obtained the desired capacitor (indicated with the reference C) that is defined by the bottom plate 145, the top plate 165 and the dielectric layer 140 being interposed between the bottom plate 145 and the top plate 165.

Moreover, further portions of the same metal layer define one or more conductive turrets 170 and a conductive turret 178 (or more) being formed above the corresponding via-holes 125 and 128, respectively. Therefore, the conductive turret 178 is electrically connected to the lower plate 145 through the via-hole 128, the conductive area 118, and the via-holes 126. Likewise, the conductive turrets 170 are electrically connected to corresponding functional components of the operative layer 110 through the via-holes 125 and the conductive areas 115.

The process continues in FIG. 1G, wherein on the whole structure so far obtained there is deposited a layer of insulating material 180, commonly called Inter-Metal Dielectric, IMD, which is used for electrically insulating and protecting the bottom plate 145, the top plate 165 and the conductive turrets 170, 178; such protective layer 180 is then planarized, for example, through a polishing process (CMP-Chemical Mechanical Polishing).

In the protective layer 180 there are then made a contact Pd, a contact Pu and one or more contacts Pf for electrically contacting the conductive turret 178 (and thus the bottom plate 145), the top plate 165, and corresponding conductive turrets 170 (and hence the corresponding functional components), respectively; each one of such contacts Pd, Pf and Pu includes a via-hole being formed in the protective layer 180, which is connected to a conductive pad being arranged on an exposed surface of the protective layer 180.

Therefore, in the above-described embodiment of the present invention the plates of the capacitor C are reversed compared to the structures being known in the art. In particular, the top plate 165 is now obtained from a portion of the metal layer of the integrated device (being already used for distributing signals and/or power supply between its functional components), while the bottom plate 145 is obtained from a portion of a dedicated layer of (refractory) metal material. This allows obtaining further advantages.

Firstly, the bottom plate 145 may be made with a very low thickness. In fact, the bottom plate 145 is contacted by the via-holes 126, which are formed under it in a previous step of the process, so that there is not any risk of a perforation thereof. In general, the thickness of the top plate 165 (typically of the order of 500-800 nm) will be greater than that of the bottom plate 145. For example, the thickness of the top plate 165 is equal to 1.2-5 times, preferably equal to 1.5-3 times, such as equal to 2 times the thickness of the bottom plate 145; in absolute terms, the thickness of the bottom plate 145 may be lower than 300 nm, preferably lower than 200 nm, and even lower than 100 nm (such as equal to 50-80 nm). As a consequence, a height difference between the top plate 165 and the conductive turrets 178, 170 (contacting the bottom plate 145 and the functional components of the integrated device, respectively) is limited; this allows making the via-holes for the corresponding contacts Pd, Pu and Pf more easily in a single etching operation. It should be noted that such result is obtained without requiring any additional step, since there is still used the metal layer being already used in the known process of manufacturing of the capacitors (with the only difference that such metal layer is used to form the top plate 165 instead of the bottom plate).

Moreover, since the metal layer is formed after the deposition (at high temperature) of the layer of insulating material, there is no longer any risk of its thermo-plastic deformation (even when such metal layer is very tick—for example, in power applications). Therefore, the metal layer (of the top plate 165) may be made without problems with a material that has a melting temperature being lower than that of the metal layer (of the bottom plate 145). For example, the melting temperature of the top plate 165 may be lower than 70%, and preferably lower than 50%, for example, equal to 30% of the melting temperature of the bottom plate 145; in absolute terms, the temperature of the top plate 165 is lower than 600° C., and preferably lower than 400° C., for example, equal to 300° C.

The various steps of a production process of an integrated device including an MIM capacitor according to another embodiment of the invention are illustrated in FIG. 2A-2G.

Considering in particular FIG. 2A, the description of the production process begins once a functional substrate 205 is obtained. As above, such functional substrate 205 includes the operative layer 110 (which includes the functional components of the integrated device), the conductive areas 115 (for electrically connecting the functional components included in the operative layer 110), and the pre-metal layer 120 (but without any conductive area for contacting the bottom plate of the capacitor).

Turning now to FIG. 2B, in the pre-metal layer 120 of the substrate 205 there are similarly made the via-holes 125 for contacting the conductive areas 115 (and thus the functional components included in the operative layer 110).

With reference now to FIG. 2C, the production process continues with the deposition on the functional substrate 205 of the metal layer 130, on which a layer of insulating material 135 is then deposited.

Subsequently, the layer of insulating material 135 is patterned through a masking and etching operation. The result of such operation is illustrated in FIG. 2D after the stripping of the respective mask, in which the dielectric layer 140 of the capacitor and an extension 240 thereof have been obtained. For example, the extension 240 is a tab (with a width of 1-2 μm), which extends beyond the dielectric layer 140 for 5-10 μm.

The process continues in FIG. 2E, with the deposition of the metal layer 160 on the dielectric layer 140 and on its extension 240, and on portions of the layer of metal material 130 being not covered by them. Then, the metal layer 160 is patterned through a masking and etching operation; a further etching operation is then used to remove exposed portions of the layer of metal material 130.

The result of such operations is shown in FIG. 2F after the stripping of the respective mask. As it can be seen, a remaining portion of the layer of metal material 130 on the functional substrate 205 defines the bottom plate 145 of the capacitor C and an extension 245 thereof, as well as conductive sockets 247 (on the via-holes 125). The extension 245 of the bottom plate 145 is formed under the extension 240 of the dielectric layer 140 and it also extends slightly beyond it (for example, with the same tab shape having equal width and higher length of 0.7-0.9 μm). In addition, portions of the metal layer being protected by the mask during the etching operation define the top plate 165 of the capacitor (on the dielectric layer 140), the conductive turrets 170 (on the conductive sockets 247) and another conductive turret 250; such conductive turret 250 covers the extension 245 of the bottom plate 145 being not covered by the extension 240 of the dielectric layer 140, and a border portion of the extension 245 of the bottom plate 145 (for example, for 0.1-0.3 μm).

Therefore, the conductive turret 250 is electrically connected to the bottom plate 145 of the capacitor C through the corresponding extension 245. It should be noted that the formation of the conductive turret 250 on part of the extension 240 of the dielectric layer 140 ensures the continuity of the connection of the conductive turret 250 to the bottom plate 145; in fact, the extension 240 of the dielectric layer 140, extending till under the turret 250, covers, thereby protecting it, a portion of the extension 245 of the bottom plate 145 (between the dielectric layer 140 and the conductive turret 250), which otherwise would risk being removed during the above-described etching operation of the exposed portions of the metal layer 130.

The process continues in FIG. 2G, in which on the whole structure so far obtained there is deposited and polished the protective layer 180.

In the protective layer 180 there are then made the contacts Pu and Pf (for electrically contacting the top plate 165 and the functional components, respectively), and a contact Pd′ (analogously formed by a via-hole and a conductive pad) for electrically contacting the conductive turret 250 (and thus the bottom plate 145 through the corresponding extension 245).

The above-described embodiment has all the above-cited advantages (being due to the bottom plate 145 of refractory material and possibly thin). Furthermore, such embodiment has the additional advantage that it does not need a conductive path in the insulating layer of the functional substrate for contacting the bottom plate 145. This involves a greater implementation simplicity of the production process.

Naturally, in order to satisfy local and specific requirements, a person skilled in the art may apply to the solution described above many logical and/or physical modifications and alterations. More specifically, although the present invention has been described with a certain degree of particularity with reference to preferred embodiment(s) thereof, it should be understood that various omissions, substitutions and changes in the form and details as well as other embodiments are possible. In particular, the same solution may even be practiced without the specific details set forth in the preceding description for providing a more thorough understanding thereof; on the contrary, well known features may have been omitted or simplified in order not to obscure the description with unnecessary particulars. Moreover, it is expressly intended that specific elements and/or method steps described in connection with any disclosed embodiment of the invention may be incorporated in any other embodiment as a matter of general design choice.

In particular, the above-described production processes of the capacitor are merely illustrative and in no way (imitative. For example, the same result may be obtained with equivalent processes (by using similar steps, removing some steps being not essential, or adding further optional steps), and the steps may be performed in different order, concurrently or in an interleaved way (at least partly).

Moreover, nothing prevents making the bottom plate of any other refractory material; for example, it is possible to use conductive materials (even non-metallic ones) being properly processed for obtaining lower plates that are capable of withstanding extreme process temperatures, such as in case there are requested ultra-performing dielectric layers (deposited at particularly high temperatures), or alloys including both metal materials and non-metal materials, in any combination and in any relative stoichiometric ratio.

The same considerations apply if the deposition of the layer of insulating material is made at different pressures and/or temperatures, or by other techniques, such as “Chemical Vapor Deposition” (CVD) or “Physical Electrical Chemical Vapor Deposition” (PECVD).

Moreover, the layer of insulating material may be formed of any other material (for example, silicon oxide), compatibly with the process operations, the used deposition technique and the desired quality of the dielectric layer.

Similar considerations apply if the top plate has a different melting temperature—for example, substantially equal to or slightly lower than the one of the bottom plate—in case there are provided (after the formation of the capacitor) further processes at high temperature.

Nothing prevents having the bottom plate with a thickness equal to or greater than the one of the top plate. In general, the two plates of the capacitor may be formed with different thickness ratios, depending on the production process, the available technology and the specific application.

Similar considerations apply if the conductive sockets are not present; in this case, the functional turrets may be formed directly on the conductive substrate (without any conductive socket); vice-versa, a conductive socket may also be provided under the turret for contacting the bottom plate of the capacitor.

The extension of the bottom plate may have any other shape and/or size; in addition, nothing prevents forming such structure in any other way; in particular, the extension of the bottom plate may also be equal to the extension of the dielectric layer (with the corresponding turret that contacts the bottom plate of the capacitor laterally). Furthermore, the extension of the dielectric layer on the extension of the bottom plate may also be not provided (for example, by using proper protective masks).

Moreover, similar considerations apply if the integrated device has a different structure or includes equivalent components; moreover, the elements may be separated to each other or combined together, in whole or in part. For example, each element of the integrated device may have any shape and/or size, and may be formed of any other material.

Furthermore, the integrated device may include several capacitors and different or further components. In particular, the integrated device may be provided with multiple metal layers; for example, the integrated device may be covered by another layer of insulating material, in which there are then formed via-holes being electrically connected to an outer surface of the integrated device. The same procedure may be repeated in a similar way for further metal layers. In this way, it is possible to integrate several capacitors and different or additional components within the integrated device; therefore, the MIM capacitor of the solution according to the described embodiment may be integrated with other types of capacitors, such as standard capacitors, being formed, for example, in upper metal layers of the integrated device.

The design of the integrated device may also be created in a programming language; moreover, if the designer does not manufacture the electronic devices or the masks, the design may be transmitted by physical means to others. In any case, the resulting integrated device may be distributed by its manufacturer in raw wafer form, as a bare die, or in packages. Moreover, the proposed solution may be integrated with other circuits in the same chip, or it may be mounted in intermediate products (such as mother boards) and coupled with one or more other chips (such as a processor or a memory).

In any case, the integrated device of the solution according to an embodiment of the invention is suitable to be used in complex systems (such as mobile phones).

Having thus described at least one illustrative embodiment of the invention, various alterations, modifications and improvements will readily occur to those skilled in the art. Such alterations, modifications, and improvements are intended to be part of this disclosure, and are intended to be within the spirit and the scope of the present invention. Accordingly, the foregoing description is by way of example only and is not intended to be limiting. The present invention is limited only as defined in the following claims and the equivalents thereto. 

What is claimed is:
 1. A method for producing an integrated device including an MIM capacitor, the method including the steps acts of: providing a functional substrate including functional circuits of the integrated device, forming a first conductive layer including a first plate of the capacitor on the functional substrate, the first plate having a first melting temperature, depositing a layer of insulating material including a dielectric layer of the capacitor on a portion of the first conductive layer corresponding to the first plate, the layer of insulating material being deposited at a process temperature being greater than approximately 400° C. and lower than the first melting temperature, forming a second conductive layer including a second plate of the capacitor on a portion of the layer of insulating material corresponding to the dielectric layer, wherein the first melting temperature is higher than 500° C., and wherein the second conductive layer further includes functional connections to the functional circuits, the method further including the steps of: forming a protective layer of insulating material covering the second plate and the functional connections; forming a first contact for contacting the first plate through the functional protective layer; and forming a second contact and functional contacts for contacting the second plate and the functional connections, respectively, through the protective layer.
 2. The method according to claim 1, wherein the first plate includes a titanium-nitride alloy.
 3. The method according to claim 1, wherein the process temperature is higher than 600° C. and the first melting temperature is higher than 700° C.
 4. The method according to claim 1, wherein the dielectric layer includes a silicon-nitride compound, an insulating ONO, or a combination thereof.
 5. The method according to claim 1, wherein the step of depositing a layer of insulating material is performed through an LPCVD chemical vapor deposition process.
 6. The method according to claim 1, wherein the second plate has a second melting temperature being lower than the first melting temperature.
 7. The method according to claim 1, wherein the first plate has a first thickness and the second plate has a second thickness being higher than the first thickness.
 8. The method according to claim 1, wherein the first conductive layer includes an extension of the first plate extending in plain view beyond the dielectric layer, and wherein the second conductive layer includes a further connection separate portion being formed on the extension of the first plate, the step of forming the first contact including contacting the further connection separate portion through the protective layer.
 9. An integrated device including a capacitor, the integrated device including: a functional substrate including functional circuits of the integrated device, a first plate of the capacitor on the functional substrate being obtained from a first conductive layer formed on the functional substrate, the first plate having a first melting temperature, a dielectric layer of the capacitor on the first plate being obtained from a layer of insulating material deposited on a portion of the first conductive layer corresponding to the first plate, the layer of insulating material being deposited at a process temperature being greater than approximately 400° C. and lower than the first melting temperature, a second plate of the capacitor on the dielectric layer being obtained from a second conductive layer formed on a portion of the layer of insulating material corresponding to the dielectric layer, wherein the first melting temperature is higher than 500° C., wherein the second conductive layer further includes functional connections to the functional circuits, the electronic device further including: a protective layer of insulating material covering the second plate and the functional connections; a first contact for contacting the first plate through the functional protective layer; and a second contact and functional contacts for contacting the second plate and the functional connections, respectively, through the protective layer.
 10. The integrated device according to claim 9, wherein the first plate includes a titanium-nitride alloy.
 11. The integrated device according to claim 9, wherein the dielectric layer includes a silicon-nitride compound, an insulating ONO, or a combination thereof.
 12. The integrated device according to claim 9, wherein the second plate has a second melting temperature being lower than the first melting temperature.
 13. The integrated device according to claim 9, wherein the first plate has a first thickness and the second plate has a second thickness being higher than the first thickness.
 14. The integrated device according to claim 9, wherein the first conductive layer includes an extension of the first plate extending in plain view beyond the dielectric layer, and wherein the second conductive layer includes a further connection separate portion on the extension of the first plate, the first contact contacting the further connection separate portion through the protective layer. 